Effect of Copper Oxide and Silver Nanoparticles on the Development of Tolerance to Alternaria alternata in Poplar in Vitro Clones

[1]  А. А. Гусев,et al.  Фотокаталитически активные наночастицы оксида цинка и диоксида титана в клональном микроразмножении растений: перспективы , 2020 .

[2]  S. Shivalkar,et al.  Green synthesis of metallic nanoparticles as effective alternatives to treat antibiotics resistant bacterial infections: A review , 2020, Biotechnology reports.

[3]  Moazzameh Ramezani,et al.  Effect of Silver Nanoparticle Treatment on the Expression of Key Genes Involved in Glycosides Biosynthetic Pathway in Stevia rebaudiana B. Plant , 2019, Sugar Tech.

[4]  N. Kavroulakis,et al.  Use of copper, silver and zinc nanoparticles against foliar and soil-borne plant pathogens. , 2019, The Science of the total environment.

[5]  M. Chandrasekaran,et al.  Chitosan and chitosan nanoparticles induced expression of pathogenesis-related proteins genes enhances biotic stress tolerance in tomato. , 2019, International journal of biological macromolecules.

[6]  W. Ding,et al.  Various antibacterial mechanisms of biosynthesized copper oxide nanoparticles against soilborne Ralstonia solanacearum , 2019, RSC advances.

[7]  Jian Yao,et al.  Chloroplasts at the Crossroad of Photosynthesis, Pathogen Infection and Plant Defense , 2018, International journal of molecular sciences.

[8]  Kareem A. Mosa,et al.  Copper Nanoparticles Induced Genotoxicty, Oxidative Stress, and Changes in Superoxide Dismutase (SOD) Gene Expression in Cucumber (Cucumis sativus) Plants , 2018, Front. Plant Sci..

[9]  M. Deabes,et al.  Impact of Silver Nanoparticles on Gene Expression in Aspergillus Flavus Producer Aflatoxin B1 , 2018, Open access Macedonian journal of medical sciences.

[10]  Cuixia Chen,et al.  OsASR2 regulates the expression of a defence‐related gene, Os2H16, by targeting the GT‐1 cis‐element , 2017, Plant biotechnology journal.

[11]  U. Bora,et al.  Nanotechnology in Crop Protection , 2018 .

[12]  G. Yakovleva,et al.  The Effect of Silver and Copper Nanoparticles on the Wheat—Pseudocercosporella herpotrichoides Pathosystem , 2017, Nanoscale Research Letters.

[13]  João P. Bezerra Neto,et al.  Transcription Factors Involved in Plant Resistance to Pathogens. , 2017, Current protein & peptide science.

[14]  E. Fortunati,et al.  Nanomaterials in Plant Protection , 2017 .

[15]  G. An,et al.  OsASR5 enhances drought tolerance through a stomatal closure pathway associated with ABA and H2O2 signalling in rice , 2016, Plant biotechnology journal.

[16]  P. S. Adwani,et al.  Preparation and characterization of copper oxide nanoparticles and determination of enhancement in critical heat flux , 2017 .

[17]  Tikam Chand Dakal,et al.  Mechanistic Basis of Antimicrobial Actions of Silver Nanoparticles , 2016, Frontiers in microbiology.

[18]  R. Sivaraj,et al.  Synthesis and characterization of Eichhornia-mediated copper oxide nanoparticles and assessing their antifungal activity against plant pathogens , 2016, Bulletin of Materials Science.

[19]  C. Stalikas,et al.  Qualitative Alterations of Bacterial Metabolome after Exposure to Metal Nanoparticles with Bactericidal Properties: A Comprehensive Workflow Based on (1)H NMR, UHPLC-HRMS, and Metabolic Databases. , 2016, Journal of proteome research.

[20]  T. Watson,et al.  Effect of TiO2 Photoanode Porosity on Dye Diffusion Kinetics and Performance of Standard Dye-Sensitized Solar Cells , 2016 .

[21]  Prashanth Suravajhala,et al.  Toxicity and tolerance of aluminum in plants: tailoring plants to suit to acid soils , 2016, BioMetals.

[22]  R. C. Kasana,et al.  Copper Nanoparticles in Agriculture: Biological Synthesis and Antimicrobial Activity , 2016 .

[23]  Z. Cheng,et al.  Cloning and stress response analysis of the PeDREB2A and PeDREB1A genes in moso bamboo (Phyllostachys edulis). , 2015, Genetics and molecular research : GMR.

[24]  Katarzyna Turnau,et al.  Antifungal properties of silver nanoparticles against indoor mould growth. , 2015, The Science of the total environment.

[25]  Utkarsha U. Shedbalkar,et al.  Bacteriagenic silver nanoparticles: synthesis, mechanism, and applications , 2015, Applied Microbiology and Biotechnology.

[26]  Sandhya Mishra,et al.  Biosynthesized silver nanoparticles as a nanoweapon against phytopathogens: exploring their scope and potential in agriculture , 2015, Applied Microbiology and Biotechnology.

[27]  C. Dendrinou-Samara,et al.  Synthesis, characterization and evaluation of copper based nanoparticles as agrochemicals against Phytophthora infestans , 2013 .

[28]  R. Kaveh,et al.  Changes in Arabidopsis thaliana gene expression in response to silver nanoparticles and silver ions. , 2013, Environmental science & technology.

[29]  J. White,et al.  Xylem- and phloem-based transport of CuO nanoparticles in maize (Zea mays L.). , 2012, Environmental science & technology.

[30]  J. Jung,et al.  Antifungal Effects of Silver Nanoparticles (AgNPs) against Various Plant Pathogenic Fungi , 2012, Mycobiology.

[31]  M. Dasgupta,et al.  Pathogenesis-related genes and proteins in forest tree species , 2010, Trees.

[32]  J. Jung,et al.  The Effect of Nano-Silver Liquid against the White Rot of the Green Onion Caused by Sclerotium cepivorum , 2010, Mycobiology.

[33]  S. Duplessis,et al.  Poplar and Pathogen Interactions: Insights from Populus Genome-Wide Analyses of Resistance and Defense Gene Families and Gene Expression Profiling , 2009 .

[34]  Weilun Yin,et al.  Expression profiling and functional characterization of a DREB2-type gene from Populus euphratica. , 2009, Biochemical and biophysical research communications.

[35]  R. Sturrock,et al.  Host-Pathogen Interactions in Douglas-Fir Seedlings Infected by Phellinus sulphurascens. , 2007, Phytopathology.

[36]  Jianhua Zhu,et al.  Cold stress regulation of gene expression in plants. , 2007, Trends in plant science.

[37]  J. Bohlmann,et al.  The transcriptional response of hybrid poplar (Populus trichocarpa x P. deltoides) to infection by Melampsora medusae leaf rust involves induction of flavonoid pathway genes leading to the accumulation of proanthocyanidins. , 2007, Molecular plant-microbe interactions : MPMI.

[38]  P. Wincker,et al.  Transcript Profiling of Poplar Leaves upon Infection with Compatible and Incompatible Strains of the Foliar Rust Melampsora larici-populina1[W] , 2007, Plant Physiology.

[39]  F. J. Corpas,et al.  Cytosolic NADP-isocitrate dehydrogenase of pea plants: Genomic clone characterization and functional analysis under abiotic stress conditions , 2007, Free radical research.

[40]  K. Shinozaki,et al.  Gene networks involved in drought stress response and tolerance. , 2006, Journal of experimental botany.

[41]  R. Sunkar,et al.  Drought and Salt Tolerance in Plants , 2005 .

[42]  A. Ekramoddoullah Physiology and Molecular Biology of a Family of Pathogenesis-Related PR-10 Proteins in Conifers , 2004 .

[43]  Y. Kamiya,et al.  The Arabidopsis cytochrome P450 CYP707A encodes ABA 8′‐hydroxylases: key enzymes in ABA catabolism , 2004, The EMBO journal.

[44]  H. Bohnert,et al.  Genomic approaches to plant stress tolerance. , 2000, Current opinion in plant biology.

[45]  J. Kangasjärvi,et al.  Induction of genes for the stress proteins PR-10 and PAL in relation to growth, visible injuries and stomatal conductance in birch (Betula pendula) clones exposed to ozone and/or drought. , 1998, The New phytologist.

[46]  D. Klessig,et al.  Two inducers of plant defense responses, 2,6-dichloroisonicotinec acid and salicylic acid, inhibit catalase activity in tobacco. , 1995, Proceedings of the National Academy of Sciences of the United States of America.